Panspatial Genesis and the Hyperfractal Organization of Life

This paper introduces the Fundamental Theorem of Panspatial Genesis, which states that life is not an accidental anomaly imposed upon matter after chemistry has already formed, but a structurally admissible outcome of coherence spaces satisfying specific FCHP Finsler Coherence Hyperfractal Phase-Space Topology and Geometry conditions. These conditions include intrinsic torsion, chirality, coherence-gradient stability, hyperfractal resonance organization, and recursive boundary stratification. Within the Unified Coherence Closure Framework, the interval between 3.14D coherence-curvature equilibrium and 3.0D spatial closure is identified as the ACO band, or atomic-continuum partial-closure band. This band contains turbulence, fractal recursion, quantum partial closure, and boundary pre-formation. The hyperfractal is here defined not as a merely geometric fractal, but as a resonance operator that organizes asymmetry across scale, phase, gradient, and boundary depth. Life emerges when this organized asymmetry becomes recursively stabilized as boundary-bearing identity. The paper argues that biology is therefore the hyperfractal continuation of physics into self-maintaining boundary closure. Chemistry remains essential, but is interpreted as the local atomic expression of a deeper panspatial admissibility architecture. Keywords Panspatial Genesis; Hyperfractal Resonance; FCHP; ACO Band; Infratier Closure Physics; Organized Asymmetry; Boundary Identity; Coherence Gradients; Partial Closure; Origin of Life; Unified Coherence Closure Framework. Orientation The central problem of life is usually framed as a chemical problem: how nonliving molecules became living systems. This paper accepts the importance of chemistry, but argues that chemistry alone does not explain why life is structurally possible in the first place. Before there can be metabolism, replication, coding, or cells, there must be a deeper admissibility structure capable of supporting: The question therefore becomes deeper than abiogenesis in the ordinary sense. The deeper question is: What kind of reality allows boundary-bearing identity to emerge at all? Within the Unified Coherence Closure Framework, the answer is that life becomes possible where coherence spaces satisfy the conditions of FCHP: Finsler-directional structure, intrinsic torsion, chirality, coherence-gradient stability, and hyperfractal resonance organization. Life is not inserted into physics from outside. Life is what physics becomes when asymmetry is recursively organized into boundary-maintaining identity.